KR100467150B1 - Device and method for displaying base station type in cdma communication system - Google Patents

Abstract

A receiving device of a terminal communicating with at least two different types of base stations generates frequency channel control data of the base station at a base station discovery time, and analyzes signals received from base stations of a set frequency channel to register settings of the base stations. A control unit, an RF unit configured to receive a received RF frequency band by frequency channel control data and down converting a signal received in the set frequency band, and a searcher for measuring the intensity of the received signal output from the RF unit and outputting the received signal to the control unit And a display unit for displaying base stations set and registered by the control unit.

Description

DEVICE AND METHOD FOR DISPLAYING BASE STATION TYPE IN CDMA COMMUNICATION SYSTEM}

The present invention relates to a terminal receiving apparatus and method, and more particularly, to a device and a method for identifying and displaying a type of a base station.

In general, the code division multiple access (hereinafter referred to as CDMA) mobile communication system has been developed from the conventional mobile communication standard mainly on voice, and is an IMT-2000 standard capable of transmitting high speed data as well as voice. It has developed. In the IMT-2000 standard, services such as high quality voice, moving picture, and internet search are possible. In the CDMA mobile communication system, a communication line existing between a terminal and a base station is largely divided into a reverse link from a terminal to a base station as opposed to a forward link from a base station to a terminal.

In general, the conventional CDMA communication system does not feel very inconvenient in the case of voice communication, but does not maintain sufficient communication quality in the conventional method in data communication requiring high transmission speed and high quality call quality. In addition to voice, CDMA mobile communication system must have channels to service voice and data in order to provide various multimedia data services such as data communication including packet data communication and high quality voice communication. do. The base station apparatus as described above can service voice and data communication. Such a base station apparatus is called a CDMA 1X base station apparatus.

In recent years, many studies have been made to enable high-speed data transmission in a code division multiple access mobile communication system (hereinafter referred to as a "CDMA system"). A representative mobile communication system having a channel structure for high speed data transmission is a so-called "High Data Rate (HDR)" (or HDR system). The HDR system is a mobile communication system of the HDR standard proposed by the 3rd Generation Partnership Project 2 (3GPP2) to complement the data communication of the IS-2000 system.

The HDR system uses a link adaptation method that adjusts a data rate by changing a coding rate and a modulation method according to a channel state. In the forward link of the HDR system, a pilot channel, a forward media access control (MAC) channel, a forward traffic channel, and a forward control channel are time division multiplexed (TDM) and transmitted. The forward traffic channel using the link adaptation method has three modulation schemes: Quadrature Phase Shift Keying (QPSK), 8-ary Phase Shift Keying (8PSK), and 16-ary Quadrature Amplitude Modulation (16QAM), 1/4, 3 / A combination of three coding rates of 8 and 1/2 and the number of slots in which packets are repeatedly transmitted enables transmission at data rates according to 13 transmission schemes. The base station apparatus as described above is a device capable of serving only data communication. Such a base station apparatus is called a CDMA 1X EVDO base station apparatus.

In this case, when the type of the base station apparatus is different as described above, the user should have different terminals according to the type of the base station apparatus. That is, since the channel structure is different depending on the type of the base station, the terminal should also be used independently according to the type of the base station. In addition, the IMT 2000 CDMA communication system includes a CDMA method centering on North America and a UMTS method centering on Europe.

Currently, terminals that can communicate with a North American CDMA 1X base station device and an EVDO base station device are being developed. When the CDMA communication system is fully serviced in the future, it is possible to communicate with a North American CDMA base station device and a European UMTS base station device. Are expected to be developed. At this time, when using a terminal that can communicate with at least two types of base station devices as described above, the user should check which base station devices can communicate with the current location of the terminal.

Accordingly, an object of the present invention is to provide a receiver and method for a terminal capable of determining base station apparatuses by analyzing channel signals transmitted from at least two kinds of base station apparatuses in a code division multiple access communication system.

Another object of the present invention is to provide a receiving apparatus and method for a terminal capable of distinguishing and displaying the type of code division multiple access communication system serving data communication with the base station apparatus of the code division multiple access communication system serving voice and data communication. In providing.

Another object of the present invention is to provide a receiver and a method of a terminal capable of distinguishing and displaying base stations using the same spreading sequence and using different frequency bands.

In order to achieve the above object, a receiver of a terminal communicating with at least two different types of base stations according to an embodiment of the present invention generates frequency channel control data of a base station at a base station discovery time, and sets base stations of a set frequency channel. A control unit for registering the settings of the base stations by analyzing the signals received from the base station; a receiving RF frequency band is set by the frequency channel control data; and an RF unit down-converting the signal received in the set frequency band; And a searcher for measuring the intensity of the received signal output from the controller and outputting the signal to the controller, and a display unit for displaying the base stations set and registered by the controller.

Further, in order to achieve the above object, a receiving apparatus of a terminal of a code division multiple access communication system for communicating with a first base station serving voice and data and a second base station serving data only, the first base station at a first search time. Generating the frequency channel control data allocated to the second base station and generating the frequency channel control data allocated to the second base station at a second search time, and analyzing the signals received from the base stations of the set frequency channel. A control unit for registering a signal, a receiving RF frequency band is set by the frequency channel control data, an RF unit for down-converting a signal received in the set frequency band, and a specific channel of the first base station output from the RF unit. A first data processing unit including a searcher for measuring the received signal strength of the signal and outputting the received signal to the controller; A second data processing unit having a searcher for measuring the received signal strength of a specific channel of the second base station output from the conventional RF unit and outputting the received signal to the control unit; and a registered first and / or second base station set by the control unit. Characterized in that it consists of a display unit for displaying.

In an embodiment of the present invention for achieving the above object, a method for identifying a base station of a terminal communicating with at least two different types of first base station and second base stations includes selecting the first base station at a first search time. Outputting first frequency channel control data for determining whether the first base station is registered by measuring a signal received from the frequency channel, and a second search time generated after a predetermined time elapses from the first search time Outputting second frequency channel control data for selecting the second base station, determining whether to register the setting of the second base station by measuring a signal received in the frequency channel, and the first base station and the second base station; And registering the registration of the first base station and / or the second base station according to whether the base station registers the configuration.

In addition, the base station identification method of the terminal communicating with at least two different types of first base station and the second base station, outputs the first frequency channel control data for selecting the first base station at the first search time, the frequency Determining whether to register the setting of the first base station by measuring a signal received from the channel; and a second frequency channel for selecting the second base station at a second search time generated after a predetermined time elapses from the first search time. Outputting control data, determining whether to register the setting of the second base station by measuring a signal received in the frequency channel, and whether or not the first base station and the second base station are registered to be registered. Or) displaying the registration of the second base station.

The method for identifying a base station of a terminal communicating with at least two different types of first and second base stations includes outputting first frequency channel control data for selecting the first base station in a search time, and then outputting the first frequency channel control data. It is determined whether to register the setting of the first base station by measuring the received signal, and subsequently outputs the second frequency channel control data for selecting the second base station, and then measures the signal received on the frequency channel to measure the second base station. Determining whether the base station is registered for setting, and displaying the registration of the first base station and / or the second base station according to whether the first base station and the second base station are registered.

In addition, a base station identification method of a terminal communicating with at least two different types of first and second base stations outputs a first frequency channel control data for selecting the first base station every search time, Determining whether to register the setting of the first base station by measuring the received signal; and outputting second frequency channel control data for selecting the second base station in the call mode, and measuring the signal received on the frequency channel. Determining whether to register the setting of the second base station, and displaying registration of the first base station and / or the second base station according to whether the first base station and the second base station are registered. It is done.

1 is a diagram illustrating a transmission channel structure of a base station apparatus of a code division multiple access communication system for performing voice and data services;

FIG. 2 is a diagram showing the structure of the channel signal generator of FIG.

3 is a diagram illustrating the structure of a complex spreader and an RF transmitter of FIG.

4 is a diagram illustrating a transmission channel structure of a base station apparatus of a code division multiple access communication system for performing data service;

5 is a diagram showing the detailed structure of FIG.

6 is a diagram illustrating a structure of a receiver of a terminal of a code division multiple access communication system according to an embodiment of the present invention.

FIG. 7 is a diagram illustrating a structure of a searcher in the data processor of FIG. 5. FIG.

8A and 8B illustrate a procedure for distinguishing a base station apparatus in a terminal according to the first embodiment of the present invention.

9 is a diagram illustrating a procedure for identifying a base station apparatus in a terminal according to a second embodiment of the present invention.

10 is a diagram illustrating a procedure for distinguishing a base station apparatus in a terminal according to a third embodiment of the present invention.

11A and 11B illustrate communication states of a plurality of base station apparatuses according to an embodiment of the present invention.

DETAILED DESCRIPTION A detailed description of preferred embodiments of the present invention will now be described with reference to the accompanying drawings.

In the following description, specific details such as types of base stations, parameters for distinguishing types of base stations, etc. are shown to provide a more general understanding of the present invention. It will be apparent to one of ordinary skill in the art that the present invention may be readily practiced without these specific details and also by their modifications.

In the following description, it is assumed that the first base station is a CDMA base station apparatus that performs voice and data communication services, and the second base station is assumed to be a CDMA Evolution Data Only (EVDO) base station apparatus that provides data communication only. . Currently, CDMA base stations and CDMA EVDO base stations use the same pseudo random noise sequence (PN) and use different frequency bands. CDMA base stations also use the same PN sequence and use frequencies in different bands. Therefore, the embodiment of the present invention will be described by taking a method of determining the type of the base station by analyzing the received signal according to the channel frequency of the base station.

1 is a diagram showing a transmission channel structure of a base station apparatus of a CDMA 1X communication system serving voice and data.

First, referring to the channel configuration of the base station, the dedicated control channel signal generator 103 is responsible for processing and transmitting various control messages transmitted through a dedicated control channel (DCCH) of the forward link to the terminal. Referring to the operation of the dedicated control channel signal generator 103, the messages transmitted through the dedicated control channel of the forward link are RLP (Radio Link Protocol) frames or various control messages (L3 signaling) used in the IS-95B and additional channels. And a Medium Access Control (MAC) message, which is a control message related to packet data service control such as allocating and releasing an additional channel. When the base channel is not used, the power control signal may be transmitted through a dedicated control channel. In this case, the control message may include the power control signal. In addition, in the forward dedicated control channel, a data rate to be used for the base station and the additional channel is negotiated, and when the orthogonal code is used for the additional channel, a command for changing the orthogonal code is also issued.

The pilot channel signal generator 105 is responsible for processing and transmitting the information transmitted through the pilot channel (pilot channel) of the forward link to the terminal. The pilot channel signal of the forward link always transmits a logic signal 0 or 1 (all 0's or all 1's). In this case, it is assumed that 0 logic signal is output to the pilot channel. The pilot channel signal allows the terminal to quickly acquiesce a new multipath and to estimate the channel. The pilot channel signal is spread by assigning one predetermined orthogonal code to a pilot channel.

The synchronization channel signal generator 107 is responsible for processing and transmitting information transmitted through a sync channel of a forward link to the terminal. Information transmitted through the synchronization channel is information for allowing terminals in a cell to match initial time synchronization and frame synchronization. A predetermined predetermined Walsh code is assigned to the sync channel of the forward link to spread the information of the sync channel.

The paging channel signal generator 109 is responsible for processing and transmitting information transmitted through a paging channel of the forward link to the terminal. The information transmitted on the paging channel is all the information needed before the communication channel is established. The paging channel of the forward link selects and spreads one of predetermined orthogonal codes.

The base channel signal generator 111 is responsible for processing and transmitting information transmitted through a fundamental channel of the forward link to the terminal. Information transmitted on the base channel of the forward link is basically a voice signal. In addition, the information transmitted through the base channel of the forward link may include various control messages (L3 signaling) and power control signals used in the IS-95B in addition to the voice signal. In addition, if necessary, a signal transmitted through the base channel of the forward link may include an RLP frame and a MAC message.

The additional channel signal generator 113 is responsible for processing and transmitting information transmitted through the supplemental channel of the forward link to the terminal. Information transmitted through the additional channel of the forward link is an RLP frame, packet data, and the like. The additional channel signal generator 113 has a data rate of 9.6 kbps or more. The additional channel signal generator 113 has a scheduled data rate. As described above, the scheduled rate means that the base station and the terminal negotiate through the dedicated control channel to communicate at a data rate determined by the base station. The additional channel signal generator 113 of the forward link is assigned an unused orthogonal code among the unassigned orthogonal codes which are not assigned to the pilot channel signal generator 105, the synchronization channel signal generator 107, and the paging channel signal generator 109 so as to receive the additional channel signal. Diffuse output. In this case, the basic channel and the additional channel become a communication channel.

The adder 115 is configured to transmit the I-channel transmission signals of the forward link output from the dedicated control channel signal generator 103, the basic channel signal generator 111, and the additional channel signal generator 113, the pilot channel signal generator 105, the synchronization channel signal generator 107, and the paging channel signal. The transmission signal output from the generator 109 is added and output. The adder 117 adds and outputs the Q channel transmission signals output from the dedicated control channel signal generator 103, the basic channel signal generator 111, and the additional channel signal generator 113. A complex PN spreader 119 spreads the transmission signal output from the adder 115 and the adder 117 by the PN spreading sequence. The RF transmitter 121 performs a function of frequency raising conversion of the PN spread transmission signal at a frequency according to the set RF channel data and transmitting the same.

FIG. 2 is a diagram showing the configuration of the channel signal generator of FIG. 2 may be a channel structure of the dedicated control channel signal generator 103.

Referring to FIG. 2, the CRC generator (add 16 bit CRC) 202 generates a CRC according to the received control frame message and outputs the CRC in addition to the received message. A tail bit generator (add 8 bit encoder tail) 204 inputs the output of the CRC generator 202, generates a tail bit for notifying the end of the control message of the frame, and then outputs it in addition to the frame message.

A encoder encoder and puncturing part 206 encodes and outputs a frame control message output from the tail bit generator 204. The encoder 206 may use a convolutional encoder or a turbo encoder. An interleaver 208 interleaves and outputs symbol data output from the encoder 206. The interleaver 208 may use a block interleaver.

The long code generator 210 generates a long code. The long code is a unique identification code of each subscriber, and is differently assigned to each subscriber. A bit selector 212 decimates the long code to match the symbol rate output from the interleaver 208 and generates a selection signal for determining the insertion position of the control bit. An exclusive OR operator 214 outputs the exclusive OR of the encoded symbols output from the interleaver 208 and the long code output from the bit selector 212.

The signal converter (MUX & signal power mapping part) 216 demultiplexes the data output from the exclusive logic combiner 214 into I and Q channels so as to be transmitted, and outputs the first channel signal and the second channel signal. In addition, the signal converter 216 converts the level of symbol data, and converts 0 to +1 and 1 to -1. The first channel gain adjuster 218 inputs a first channel signal output from the signal converter 216 and adjusts and outputs a gain of the first channel signal according to a gain control signal. The second channel gain adjuster 220 inputs a second channel signal output from the signal converter 216 and adjusts and outputs a gain of the second channel signal according to a gain control signal.

An orthogonal code generator 232 generates and outputs a corresponding orthogonal code according to an orthogonal code number Wno and an orthogonal code length. Here, the orthogonal code may use a Walsh code, and may also use a quasi-orthogonal code. The multiplier 228 multiplies the first channel signal by the orthogonal code to generate a quadrature modulated first channel signal. The multiplier 230 multiplies the second channel signal by the orthogonal code to generate a quadrature modulated second channel signal.

FIG. 3 is a diagram illustrating a configuration of a complex QPSK spreader 119 and an RF transmitter 121 for spreading and modulating signals generated in respective channel generators configured as shown in FIG. 1.

Referring to FIG. 3, the multiplier 311 multiplies and outputs the I-channel orthogonal modulated signal IW and the I-channel spreading sequence PNI, and the multiplier 313 multiplies and outputs the I-channel orthogonal modulated signal QW and the I-channel spreading sequence PNI. The multiplier 315 multiplies and outputs the quadrature modulated signal QW of the Q channel and the Q channel spreading sequence PNQ, and the multiplier 317 multiplies and outputs the quadrature modulated signal IW of the I channel and the output of the Q channel spreading sequence PNQ. The subtractor 319 subtracts the output of the multiplier 315 from the output of the multiplier 311 to generate the spread signal XI of the I channel, and the adder 321 adds the output of the multiplier 313 and the output of the multiplier 317 to add the spread signal XQ of the Q channel. Occurs. Therefore, the spreader having the above configuration generates the difference between the two signals output from the multipliers 311 and 315 as the spread signal XI of the I channel, and adds the sum of the two signals output from the multipliers 313 and 317 to the spread signal XQ of the Q channel. Create The baseband filter 323 filters the I-channel spreading signal output from the subtractor 319 into the baseband, and the baseband filter 325 filters the Q-channel certain coded signal output from the adder 321 into the baseband. do. The mixer 327 mixes the output of the baseband filter 323 and the I-channel carrier cos (2πfct) to generate an I-channel RF signal, and the mixer 329 mixes the output of the baseband filter 325 and the Q-channel carrier sin (2πfct). To generate an RF signal of the Q channel. The carrier cos (2πfct) is a carrier generated by RF channel data output from a controller (not shown). The adder 331 generates RF signals by adding RF signals of I and Q channels output from the mixers 327 and 329.

As described above, the complex spreader 119 is a signal of the I channel component and the Q channel component, and the spreading sequence includes the I channel spreading sequence PNI and the Q channel spreading sequence PNQ, and thus spreads the signals of the I channel and the Q channel. Will print.

4 is a diagram illustrating a channel structure of an EVDO base station apparatus.

Referring to FIG. 4, the traffic channel signal generator 401 orthogonally spreads the received traffic signal and the preamble signal, and multiplexes them. Orthogonally spread various control information FAB, RAB, DRI and RPC received from the control information generator. The pilot channel signal generator 405 orthogonally spreads the pilot signal. The multiplexer 407 multiplexes the outputs of the traffic channel signal generator 401, the control information generator 403, and the pilot channel signal generator 405. The complex spreader 409 spreads the quadrature spread signal output from the multiplexer 407 in a PN sequence. The RF transmitter 411 raises and spreads the spread signal on a carrier wave according to RF channel data.

FIG. 5 is a diagram illustrating a detailed channel structure of the apparatus for transmitting an EVDO base station as shown in FIG. 4.

Referring to the operation of the traffic channel signal generator 401, the received traffic signal is encoded by the encoder 501, modulated by QPSK, 8PSK, 16QAM, etc. according to the transmission rate by the modulator 502, and interleaved by the interleaver 503. The interleaved traffic channel signal is punctured and repeated at the puncturing and repeater 504 according to the data rate to transmit 16 consecutive bits on the demultiplexer 505 to 16 parallel channels. Each of the 16 channels is multiplied by 16 orthogonal Walsh codes in Walsh cover processor 506 and summed at chip level in Walsh Chip Level Summer 507. The preamble is repeated according to the data rate in the preamble repeater 511 and spread by a Walsh code such as the Walsh code assigned to the reverse power control channel in the Walsh spreader 512. The traffic channel and the preamble are delivered to the second multiplexer 562 by concatenating the preamble in the first section of the traffic channel in the first multiplexer.

Hereinafter, a transmitter structure for a DRI (DRC Request Indicator, DRC) bit associated with the present invention will be described in detail. In the forward medium access channel (MAC) channel, the 0, 1, and 2 Walsh codes are multiplied by the pilot, forward, and reverse activity bits, respectively, and the remaining 29 Walsh codes are transmitted. The reverse power control bits for each user are multiplied and transmitted. One of the 29 Walsh codes used for the RPC bit (Reverse Power Control Bit) may be allocated and used for the transmission of the DRI bit. For example, Walsh 3 may be allocated to transmit the DRI bit. Therefore, according to the structure of the base station transmitter of the present invention, the FA bit is repeated 16 times in the repeater 521 to be multiplied by the Walsh number 1 by the multiplier 522, and the RA bit is repeated by the RABLength index in the repeater 531 to be RA bits by the multiplier 532. The Walsh number 2 is multiplied by, and the DRI bit is multiplied by the Walsh number 3 by the multiplier 541. The RPC bit is controlled by the RPC channel gain controller 551 by the RPC channel gain, and the multiplier 552 multiplies the remaining Walsh codes by the channel gain controlled RPC bit, respectively. The outputs of the multipliers 522, 532, 541, 552 are summed to chip level by summer 553, and the summation result by summer 553 is repeated four times by MAC channel repetition block 554 to perform the second pilot of each slot of the forward channel. It is punched halfway before and after the burst. The second multiplexer connects the output of the first multiplexer 513 and the output of the MAC channel repeater 554 as shown in FIG. 3. The second multiplexer output is complex-diffused by the complex spreader 503 and up-converted to the RF channel frequency specified by the RF transmitter 411.

As described above, it can be seen that the channel structure of the base station apparatus serving voice and data and the base station apparatus serving data only are different. In this case, the complex spreaders 119 and 409 of the base station apparatuses spread the transmission signal using the same PN sequence, and the RF transmitters 121 and 411 use allocated RF frequency channels, respectively. Accordingly, the terminal can check the type of the base station apparatus by examining the pilot channel signal while changing the RF frequency channels. That is, since the pilot channel signal is a signal of 0 or 1, the PN sequence of the base station apparatus can be confirmed by despreading the pilot channel signal. Therefore, the type of the base station apparatus can be distinguished by checking the pilot channel signal while changing the RF frequency channels.

6 is a diagram illustrating a configuration of a receiver of a terminal according to an embodiment of the present invention.

Referring to FIG. 6, the controller 602 controls the overall operation of the terminal. In addition, the controller 602 generates RF channel control data for setting an RF frequency channel according to the set discovery mode of the base station apparatus. The memory 604 is composed of a program memory for storing an operation program of a terminal and a program for determining a type of a base station apparatus and a data memory for temporarily storing data generated during program execution. The memory 604 also stores various parameters for identifying the base station apparatus according to the embodiment of the present invention. The parameter may be a system identifier (SID), a network identifier (NID), an identifier of the type of the base station apparatus, or the like. The key input unit 606 includes a number / letter key for inputting dialing and text information, a function key for setting various functions, and a menu key for menu setting. Further, according to an embodiment of the present invention, the apparatus may further include function keys for selecting base station apparatuses. The display unit 608 displays the operation state and information of the terminal under the control of the controller 602. The display unit 608 may further include an identifier indicator for displaying a registered base station according to an embodiment of the present invention to display the registered base stations. In addition, when the display unit 608 is a color LCD, the registered base stations may be displayed by changing the color of a specific identifier. The communication interface unit 610 is in charge of a communication interface between the terminal and the external communication device. The RF unit 612 is set an RF frequency channel by the RF channel control data output from the control unit 602, and transmits and receives an RF signal through the set RF frequency channel.

The first data processor 614 includes a CDMA 1X modem, demodulates and decodes a signal of a 1X base station apparatus received from the RF unit 612, and encodes and modulates a 1X system signal transmitted from a terminal. Output to 612 The first data processor 614 may include a digital signal processor (DSP). The audio processor 616 processes the audio signal processed by the first data processor 614 and outputs the audio signal to the speaker, processes the audio signal output from the microphone, and outputs the audio signal to the first data processor 614. The second data processor demodulates and decodes the EVDO base station signal output from the RF unit 612. The second data processor encodes and modulates the EVDO system signal transmitted from the terminal and outputs the signal to the RF unit 612. The second data processor 618 may also include a digital signal processor (DSP).

The first data processing unit 614 and the second data processing unit 618 respectively receive pilot signals and include a searcher for identifying the type of the base station apparatus and fingers for data demodulation. 7 is a diagram illustrating a configuration of the searcher.

Referring to FIG. 7, the data processing units 614 and 618 detect a PN sequence of a base station apparatus and a searcher for channel acquisition and a data demodulator 720 for processing a signal transmitted from the base station apparatus. Equipped.

Referring to the operation of the searcher, the terminal despreads a received signal to detect a signal transmitted from a plurality of base stations using the same RF frequency channel, and measures a received signal level, a propagation delay, or a relative propagation delay between multipaths. . Which parameter the terminal measures depends on the purpose the terminal intends to achieve. If the purpose of estimation is to measure the distance from the base station, the main measurement parameter of the terminal is the propagation delay. If the purpose of the terminal is to measure for finger assignment or handoff, then the propagation delay and signal level of each multipath will be the measurement parameters.

Referring to the operation of the searcher of the receiver of the terminal, the multiplier 712 multiplies the received signal, which is frequency down-converted by the RF unit 612, with the PN spreading code to despread the PN. The multiplier 714 performs orthogonal demodulation by multiplying the PN despread signal output from the multiplier 712 by the orthogonal code Wp assigned to the pilot channel. Therefore, the signal output from the multiplier 714 becomes a signal of a pilot channel. The accumulator 716 accumulates and outputs the output of the multiplier 714 in symbol units. The energy calculator 106 then calculates the energy of the received pilot signal. A method commonly used for calculating the energy of the despread signal is to obtain the sum of the squares of the despread values of the I and Q channels, that is, I ² + Q ² . This value is the Ec / Io of the received pilot channel. Where Ec represents the energy per chip of the received signal and Io represents the power spectral density of the entire received CDMA signal.

Then, the controller 602 detects the base station by comparing the strength of the pilot channel signal output from the energy calculator 718 with a predetermined reference value, and then determines the base station by determining information received through the predetermined channel of the base station.

In the following description, the CDMA 1X base station apparatus is referred to as a first base station, and the EVDO base station apparatus is referred to as a second base station. In addition, the terminal stores a PRC table as shown in Table 1 below in the memory 602, and stores identification information of the first base station and the second base station using the parameter information of the PRC table and the information of the base station.

Base station type SID NID frequency 1X xxxxxxxxx mmmmmmmm fa EVDO yyyyyyyyy nnnnnnnn fb

Table 1 stores system identification information SID, network identification information, and RF frequency channel control data according to a base station type.

FIG. 8A is a diagram illustrating a procedure for identifying base station apparatuses in a terminal according to the first embodiment of the present invention, and FIG. 8B is a diagram illustrating a timing at which the terminal searches for a first base station and a second base station.

First, referring to FIG. 8B, the controller 602 of the terminal searches for a base station by setting RF frequency channels of the first base station and the second base station at the first search time T1 and the second search time T2 repeated at predetermined time intervals. search). In this case, it is assumed that the first search time T1 and the second search time are alternately generated.

Referring to FIG. 8A, the controller 602 generates a first search time T1 and a second search time T2 at predetermined time intervals. When the first search time T1 is reached, the controller 602 recognizes this in step 811, and in step 813, the RF unit 612 outputs RF frequency channel control data of the first base station. Then, the RF unit 612 generates an RF frequency corresponding to the received first RF channel control data and downconverts the frequency of the received RF signal. The searcher of the first data processor 614 searches for the pilot channel signal of the first RF frequency channel, and then outputs the energy of the found pilot channel to the controller 602. Then, the controller 602 determines whether to detect the pilot signal of the searched first base station in step 815. If the search is greater than a predetermined reference value, the controller 602 determines that the first base station is detected in step 815. Set and register the first base station. Thereafter, the controller 602 receives a signal of a specific channel (synchronization channel in the case of 1X base station apparatus) of the first base station, and stores identification information of the first base station in the memory 604. In this case, the identification information may be system identification information (SID) and operator identification information (Network Identification) of the first base station. However, if the pilot signal of the first base station is not received in step 815, the controller 602 releases the setting registration of the first base station in the memory 604 in step 819.

When the second search time T2 is reached, the controller 602 recognizes this in step 821, and in step 823, the RF unit 612 outputs RF frequency channel control data of the second base station. Then, the RF unit 612 generates an RF frequency corresponding to the received second RF channel control data and downconverts the frequency of the received RF signal. After searching for the pilot channel signal of the second RF frequency channel, the searcher outputs the energy of the found pilot channel to the controller 602. The searcher may be a searcher of the first data processor 614, or may be provided independently of the second data processor 614. Then, the controller 602 determines whether to detect the pilot signal of the searched second base station in step 825. If the search is greater than a predetermined reference value, the controller 602 sets and registers the second base station in the memory 604 in step 827. Thereafter, the controller 602 receives the specific channel signal of the second base station, checks the identification information of the second base station, and stores it in the memory 604. In this case, the identification information may be system identification information (SID) and operator identification information (Network Identification) of the second base station. However, if the pilot signal of the second base station is not received in step 825, the controller 602 releases the setting registration of the second base station in the memory 604 in step 829.

Thereafter, the controller 602 checks the base stations registered in step 831. In this case, four types of registration may occur. That is, when both the first base station and the second base station are registered, only the first base station is registered, only the second base station is registered, and both the first and the second base station are not registered. . In step 833, the controller 602 displays a result according to the registered state of the base station on the display unit 608.

As shown in FIGS. 11A and 11B, the display unit 608 includes a first display area 10 for displaying a current terminal state, a second display area 20 for displaying text and image data, a second display for displaying time information, and the like. It can be composed of three areas. However, the display unit 608 may be displayed in other forms without being divided into the above areas as necessary. In the display unit 608, the first display area includes a display 11 for displaying the reception sensitivity of the terminal and a display 12 for displaying the remaining amount of the battery. 11B may further include an indicator 13 indicating a communication state with a plurality of base stations according to an embodiment of the present invention. That is, in the embodiment of the present invention, it is assumed that the first display area 10 further includes an identifier indicating the type of the base station.

To this end, the identifier of the display unit 608 includes a 1X / DO identifier, and when a corresponding base station is identified, a method of displaying a corresponding area (CDMA, DO) may be used. That is, if communication is possible with the CDMA 1X base station apparatus, 1X of the indicator 13 is displayed. If communication with the CDMA EVDO base station apparatus is possible, the DO of the indicator 13 is displayed, and communication with both base station apparatuses is possible. , Then display both 1X and DO. When the display unit 608 is a color LCD, the state may be expressed in color. That is, when the display unit 608 does not have an identifier for separately displaying the base station apparatus as shown in FIG. Can be used to indicate base station devices. That is, when only the CDMA 1X base station device is available, the indicator 11 is displayed in black. When only the CDMA EVDO base station device is available, the indicator 11 is displayed in red. When the communication is possible with both the CDMA 1X and EVDO base station devices, It is also possible to use a blue color scheme. In addition, when detecting pilot signals of the first base station and the second base station in steps 815 and 825, the previous state is determined in steps 817 and 827, respectively. In addition, the control unit 608 may display the setting registration of the corresponding base station by voice or vibration through the audio processor 616. In addition, the controller 608 may control the display unit 608 to display registered base stations in text on the display area 20.

After displaying the base station registered as described above, the controller 602 returns to step 811 and repeats the above operation.

FIG. 8A illustrates a procedure of alternately searching for a first base station and a second base station as shown in FIG. 8B at a predetermined time interval. However, when the search time comes, a method of continuously searching the first base station and the second base station may be used. 9 is a diagram illustrating a method of continuously searching for the first base station and the second base station when the search time comes.

Referring to FIG. 9, when the search time comes, the controller 602 detects this in step 911, performs steps 913 to 919 to set an RF frequency channel of the first base station, and then searches for the first base station and registers the result. do. Subsequently, steps 923 to 929 are performed to set an RF frequency channel of the second base station, and then the second base station is searched and the result is registered. Thereafter, steps 931 and 933 are performed to display the types of registered base stations in the same manner as described above.

In general, a terminal is intended for a call, and data communication may have a lower frequency than the voice call. The data communication may be a packet data service, an image data service, or the like. Therefore, the search of the second base station with low frequency of use may be less than that of the first base station, which may extend the life of the battery. FIG. 10 illustrates a method for searching by a second base station in a state where a terminal is transitioned to a communication mode.

Referring to FIG. 10, when the search time comes, the controller 602 detects this in step 1011, performs steps 1013-1019, sets an RF frequency channel of the first base station, and searches for the first base station. Register. If it is not the search time, the controller 602 checks whether a key input is generated in step 1021. At this time, the key input means that the flip or folder is turned on (open state). In addition, the key input may be a key input such as a call button, an internet access button, or the like. When the above key input occurs, the controller 602 performs steps 1023 to 1029 to set the RF frequency channel of the second base station, searches for the second base station, and registers the result. Thereafter, steps 1031 and 1033 are performed to display the type of registered base station in the same manner as described above.

8A through 10 illustrate the case in which two types of base stations are determined, the same may be applied to two or more types of base stations. In addition, although the first base station is described as a base station that serves voice and data, and the second base station is a base station that serves data only, the first base station and the second base station provide voice and data (or data only) service. It may be a different network operator serving.

In addition, the above description has been made on the assumption that the types of base stations using different RF frequency channels are determined. However, it is possible to use other base station identifiers other than the frequency channels. That is, in a CDMA communication system, base stations use different codes (PN sequences of CDMA systems of North America). Accordingly, the type of the base station may be identified by detecting the PN sequence in the searcher searching for the signal of the pilot channel. That is, the code of the base station type may be searched and identified from the signal of the pilot channel using a different code for each type of base station in addition to the RF frequency channel.

As described above, in a terminal processing a signal received from at least two types of base station apparatuses, the terminal may display the types of corresponding base stations after identifying each type of base station. Therefore, the user of the terminal has an advantage of receiving a service by selecting a desired communication function according to the types of base stations displayed on the terminal.

Claims (20)

delete delete delete A terminal receiver for communicating with at least two base stations using different channel frequencies while using the same spreading sequence, A receiving RF frequency band for each base station is set by frequency channel control data, and an RF unit for down-converting a signal received in the set frequency band; A PN despreader for PN despreading the signal output from the RF unit, an orthogonal spreader for despreading the PN despread signal with an orthogonal code of a pilot channel, and measuring the energy of the orthogonally spread pilot channel signal A searcher configured to output an energy calculator to the control unit; The search time of the base stations is sequentially set in the base station search time, and the frequency channel control data of the base station corresponding to each of the set search time is output to the RF unit, and the pilot channel received by the base stations of the set frequency channel. A control unit which registers a base station to communicate by analyzing signal strength; And a display unit for displaying the base stations registered by the control unit. 5. The apparatus as claimed in claim 4, wherein the display unit is a color display unit, and displays the registered base station by changing a color of a specific identifier on a display area to a color of the registered base station. The apparatus as claimed in claim 5, wherein the identifier is an identifier indicating a reception sensitivity. The apparatus as claimed in claim 4, wherein the display unit displays the registered base station by text. 5. The apparatus as claimed in claim 4, further comprising an audio processing unit for displaying a base station registered by voice under the control of the controller. A first base station serving voice and data and a second base station serving data, wherein the first base station and the second base station use the same spreading sequence and use different channel frequencies. In the receiver of the terminal, A frequency band for receiving a signal of the first or second base station by frequency channel control data, and an RF unit for down-converting a signal received in the set frequency band; A first data processing unit having a searcher for measuring the received signal strength of the pilot channel of the first base station output from the RF unit and outputting the received signal to the control unit; A second data processor having a searcher for measuring the received signal strength of the pilot channel of the second base station output from the RF unit and outputting the received signal to the controller; Generate and output frequency channel control data assigned to the first base station in the first search time to the RF unit, and generate frequency channel control data assigned to the second base station in the second search time and output to the RF unit. A control unit for setting a base station to communicate with by analyzing reception strength of pilot channel signals output from the first and second data processing units; And the display unit for displaying the base station set by the control unit. The method of claim 9, wherein the searcher, A PN despreader for PN despreading the received signal, An orthogonal spreader for despreading the PN despread signal into an orthogonal signal of a pilot channel; And an energy calculator configured to measure energy of the orthogonally spread pilot channel signal and output the energy to the controller. The method of claim 9, wherein the controller alternately sets the first search time and the second search time of the base stations at predetermined time intervals, and outputs frequency channel control data of the base station corresponding to the set search time. Said device. The display apparatus of claim 9, wherein the display unit is a color display unit, and the color of a specific identifier on the display area is changed to display the first color when the first base station is set, and to display the second color when the second base station is set. Wherein the first and second base stations are displayed in a third color when both are set. The apparatus as claimed in claim 12, wherein the identifier is an identifier indicating a reception sensitivity. 10. The apparatus as claimed in claim 9, wherein the display unit displays the registered base station by text. The apparatus of claim 9, further comprising an audio processor configured to voicely display a base station registered under the control of the controller. 10. The method of claim 9, wherein the display unit further comprises an identifier indicator for displaying the registration status of the first base station and the second base station on the display area, characterized in that for displaying the identifier indicator corresponding to the registered base station Device. A first base station serving voice and data and a second base station serving a data service communicate with each other. The first base station and the second base station use different channel frequencies while using the same spreading sequence. A method for identifying a base station of a terminal of a code division multiple access communication system in which a second search time alternately occurs repeatedly, Outputting first frequency channel control data for selecting the first base station at the first search time, and determining whether to set the first base station by measuring the strength of a pilot channel signal received in the selected first frequency channel; Process, Outputs second frequency channel control data for selecting the second base station at a second search time generated after a predetermined time elapses from the first search time, and measures a signal received in the selected second frequency channel to measure the first signal; Deciding whether or not to establish a base station; And setting the first base station and / or the second base station according to whether the first base station and the second base station are set. delete It communicates with a first base station serving voice and data and a second base station serving data, and using the same spreading sequence for the first base station and the second base station, using different channel frequencies, and searching time at regular intervals. In the base station identification method of the terminal of the generated code division multiple access communication system, Output channel control data for selecting a first frequency channel of the first base station at the search time, and measure the strength of the pilot channel signal of the first base station received in the selected first frequency channel to set the first base station. The process of determining whether Successively outputting channel control data for selecting a second frequency channel of the second base station, and measuring the strength of the pilot channel signal of the second base station received in the selected first frequency channel to determine whether to set the second base station; The decision making process, And displaying the registration of the first base station and / or the second base station according to whether the first base station and the second base station are set. A first base station serving voice and data and a second base station serving data, wherein the first base station and the second base station use different channel frequencies while using the same spreading sequence. In the base station identification method of the terminal, Outputs channel control data for selecting the first frequency channel of the first base station at the search time, and measures the strength of the pilot channel signal of the first base station received in the selected first frequency channel to set the first base station. To determine the process, Outputs channel control data for selecting the second frequency channel of the second base station in the call mode, and sets the second base station by measuring the strength of the pilot channel signal of the second base station received in the selected second frequency channel. The process of determining whether And displaying the settings of the first base station and / or the second base station according to whether the first base station and the second base station are registered.